JP2004322095A6 - Ceramic honeycomb structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ceramic honeycomb structure housed in a metal container through a gripping member, which does not reduce the gripping force by the gripping member even when the metal container is expanded by high-temperature exhaust gas, for example, due to engine vibration A ceramic honeycomb structure that does not move and can reduce wear due to friction with a metal container is obtained.
A convex portion substantially corresponding to a partition wall contacting the outer peripheral surface is formed substantially uniformly in the flow path direction on the outer peripheral surface of the ceramic honeycomb structure. It is preferable that the unevenness formed by the convex portion and the outer peripheral surface has a maximum surface roughness measured in the circumferential direction of 5 to 500 μm.
[Selection] Figure 1

Description

  The present invention relates to a ceramic honeycomb structure housed in a metal container via a gripping member.

  In order to protect the global environment, reduction of exhaust gas discharged from engines such as automobiles is required, and in order to meet this demand, catalytic converters for exhaust gas purification are used. One of such catalytic converters is a ceramic honeycomb catalytic converter. This ceramic honeycomb catalytic converter is activated by activating the catalyst by heating the ceramic honeycomb structure carrying the catalyst with the thermal energy possessed by the exhaust gas. Purifying gas.

  FIG. 5 is a cross-sectional view of a main part in which a conventional ceramic honeycomb catalytic converter 50 is connected to an exhaust manifold 54 with bolts 56. Hereinafter, “ceramic honeycomb catalytic converter” is abbreviated as “catalytic converter”. In FIG. 5, a catalytic converter 50 includes a metal container 51, a low-thermal expansion ceramic honeycomb structure 52 made of cordierite carrying a catalyst, a gripping member 53 interposed between the metal container 51 and the ceramic honeycomb structure 52, and the like. Become. The ceramic honeycomb structure 52 has a smooth outer peripheral surface 52a. 6 shows the ceramic honeycomb structure 52 of FIG. 5, in which (a) is a perspective view thereof, and (b) is an enlarged schematic view of the outer peripheral surface 52a. The outer peripheral surface 52 a of the ceramic honeycomb structure 52 is gripped and stored in the metal container 51 by the surface pressure of the gripping member 53 that is compressed on the inner peripheral surface 51 a of the metal container 51. The catalytic converter 52 having such a configuration is widely used in an automobile exhaust gas purification system, and is disclosed in Patent Documents 1, 2, 3, and the like.

  On the other hand, Patent Document 4 discloses that in the catalytic converter having the above-described conventional structure, the metal container is provided with at least one fixing member that fixes the holding member in the direction of the exhaust gas flow path. There is a disclosure that even if the gripping force from the side is reduced, the ceramic honeycomb structure does not move in the direction of the flow path in the metal container, and early wear and breakage of the ceramic honeycomb structure can be prevented.

Japanese Utility Model Publication No. 56-67314 Japanese Utility Model Publication No. 55-130012 Japanese Utility Model Publication No. 62-171614 JP-A-7-127443

In recent years, further reduction of exhaust gas has been demanded, and in response to this, higher output and higher temperature combustion of engines have been promoted. In addition, since the catalyst does not act when it is cold, the catalyst converter is often placed directly under the engine with a high exhaust gas temperature in order to heat up the catalyst early and bring it into an active state after the engine starts. It is becoming exposed to.
In the conventional catalytic converter 50 shown in FIG. 5, since the outer peripheral surface 52a of the ceramic honeycomb structure 52 is formed smoothly by extrusion as shown in FIG. 6B, the metal container 51 is formed by high-temperature exhaust gas. When expanded, since the ceramic honeycomb structure 52 has a low thermal expansion, the compressed state of the holding member 53 is relaxed, and the holding force of the ceramic honeycomb structure 52 is reduced. When the ceramic honeycomb structure 52 is arranged substantially upright, the outer peripheral surface 52a is not fully restrained but moves away from the gripping member 53 due to engine vibration or the like, and collides with the cone portion 51c of the metal container 51. In addition, there is a problem that it is damaged or worn early due to friction.

  On the other hand, in order to provide a holding member different from the gripping member disclosed in Patent Document 4 in the metal container, the inner peripheral surface of the metal container into which the holding member is fitted must be precisely processed, and the manufacturing cost is increased. To raise. Further, when the metal container is expanded by the high-temperature exhaust gas, the outer peripheral surface of the ceramic honeycomb structure is formed smoothly like the above-described FIG. In the case of separation due to the above, there is a problem that the metal container is damaged or worn out early due to collision and friction with the end face of the metal container.

  An object of the present invention is a ceramic honeycomb structure housed in a metal container via a gripping member, and does not reduce the gripping force by the gripping member even when the metal container expands due to high-temperature exhaust gas. An object of the present invention is to obtain a ceramic honeycomb structure that does not move away due to vibration or the like and can be less damaged or worn due to collision and friction with a metal container.

  The present invention is a ceramic honeycomb structure housed in a metal container via a gripping member, and a convex portion substantially corresponding to a partition wall contacting the outer peripheral surface is provided in a flow path direction on the outer peripheral surface of the ceramic honeycomb structure. It is characterized by being formed substantially uniformly. And as for the unevenness | corrugation formed with the said convex part and the said outer peripheral surface, the maximum height of the surface roughness measured in the circumferential direction is 5-500 micrometers. Furthermore, the convex portion is formed by extrusion molding.

  By forming irregularities on the outer peripheral surface of the ceramic honeycomb structure, the surface area of the outer peripheral surface is increased, and the ceramic honeycomb structure is securely held in the metal container via the compressed holding member. When the maximum height of the irregularities is less than 5 μm, the gripping force is small. On the other hand, when the maximum height of the irregularities exceeds 500 μm, a portion where the ceramic honeycomb structure does not contact the gripping member is formed, and the gripping force is reduced. If the unevenness formed in the ceramic honeycomb structure is substantially uniform in each cross section perpendicular to the flow path direction of the honeycomb, even if the ceramic honeycomb structure vibrates in the circumferential direction due to the gas flow, Is more securely gripped.

  Even if the metal container expands due to high-temperature exhaust gas, the gripping force of the ceramic honeycomb structure by the gripping member does not decrease, and the ceramic honeycomb structure does not move away due to engine vibration or the like. The wear of the ceramic honeycomb structure due to friction with the parts is reduced.

  In the ceramic honeycomb structure of the present invention, even when the metal container expands due to high-temperature exhaust gas, the gripping force by the gripping member does not decrease.For example, the ceramic honeycomb structure does not move away due to engine vibration or the like. Wear due to friction can be reduced.

Hereinafter, an example of a catalytic converter attached immediately below a gasoline engine for a passenger car will be described with reference to FIGS. 1 to 4 as one embodiment. FIG. 1 is a cross-sectional view in which the catalytic converter 10 is connected to the exhaust manifold 14 by friction welding at a pressure contact portion 16. FIG. 2 shows the ceramic honeycomb structure 12 in FIG. 1, (a) is a perspective view thereof, and (b) is an enlarged schematic view of the outer peripheral surface 12 a. Moreover, FIG. 3 is an example of the unevenness | corrugation formed in three places (12a-a, 12a-b, 12a-c) in FIG. 4A is an enlarged partial view after the extrusion molding of the ceramic honeycomb structure, and FIG. 4B is a cross-sectional view of a main part of the extrusion mold. 1 and 2, in the catalytic converter 10, a ceramic honeycomb structure 12 that supports a catalyst via a gripping member 13 is housed in a metal container 11. The metal container 11 is made of a high-Si spheroidal graphite cast iron material, and the inner peripheral surface 11a that houses the ceramic honeycomb structure 12 via the gripping member 13 has a hollow cylindrical shape, and a flange portion 11d that is connected to an exhaust pipe (not shown). A cone portion 11c is formed toward the head. The ceramic honeycomb structure 12 is mainly made of cordierite ceramics containing SiO ₂ , Al ₂ O ₃ , and MgO, and carries a catalyst such as activated alumina or platinum in a honeycomb exhaust gas flow passage. The ceramic honeycomb structure 12 has an outer peripheral diameter of 100 mm and a longitudinal direction of 100 mm. The gripping member 13 is made of a heat resistant ceramic fiber. When mounted on an engine such as an automobile, the exhaust gas enters the exhaust manifold 14 (indicated by IN), then flows into the ceramic honeycomb structure through the cone portion 14c, and is supported on the ceramic honeycomb structure 12. (It is not shown) It purifies | cleans and goes to an exhaust pipe through the cone part 11c (it shows by OUT).

  Here, as shown in FIG. 2, the ceramic honeycomb structure 12 has an uneven portion 12b having a maximum height of 5 to 500 μm formed on the outer peripheral surface 12a in the honeycomb flow path direction. In the example shown in FIG. 3, the unevenness is measured by tracing 10 mm in the circumferential direction with a surface roughness meter, and the unevenness is shown by being deformed and enlarged only in the vertical direction. The surface roughness meter was a surface roughness profile measuring instrument manufactured by Tokyo Seimitsu, and the stylus curvature radius was 0.025 mm and the tracing speed was 0.15 mm / s. The maximum height of the uneven portion 12b is (12a-a) 28 μm, (12a-b) 32 μm, (12a-c) 45 μm, and the like. And the ceramic honeycomb structure 12 is reliably hold | gripped by this uneven | corrugated | grooved part 12b and the surface pressure of the holding member 13 of a compression state. In this catalytic converter 10, for example, even if the metal container 11 expands due to exhaust gas exceeding 900 ° C., the holding force of the ceramic honeycomb structure 12 by the holding member 13 does not decrease, and the ceramic honeycomb structure 12 also due to engine vibration or the like. Does not move, and damage and wear due to collision and friction with the cone portion 11c of the metal container 11 are reduced.

  Next, a method for forming the ceramic honeycomb structure 12 will be described. FIG. 4A is an enlarged partial view of the ceramic honeycomb structure 12 after extrusion molding, and FIG. 4B is a cross-sectional view of the main part of the mold 20 for extrusion molding of the ceramic honeycomb structure 12. 4 (b) includes a die 21 having a large number of supply passages 21a, a discharge passage 21b that collects clay from the supply passages 21a and forms a lattice, and a ceramic honeycomb structure 12. In order to form the outer peripheral wall 12f in a predetermined shape, a masking plate 22 that adjusts the amount of dredged soil inflow, and a pressing frame that adjusts the amount of dredged clay discharged and adjusts the outer peripheral surface 12a of the ceramic honeycomb structure 12 23 or the like. In FIG. 4, the extrusion mold 20 has an extrusion direction (indicated by an arrow) from the bottom to the top, and pushes the clay from the supply passage 21a to the discharge passage 21b, thereby opening the opening shown in FIG. A molded body of the ceramic honeycomb structure 12 having 12d, the partition wall 12e having a thickness of 150 μm, and the outer peripheral wall 12f having a thickness of, for example, 250 μm. Then, by adjusting the thickness (t), diameter (Ds), and inner diameter side protrusion amount (w) of the holding frame 23 provided on the outlet side, the clay passing through the supply passage 21a and the discharge passage 21b is pressure-bonded. The outer peripheral surface 12a of the outer peripheral wall 12f is formed. The unevenness 12b formation is controlled by the diameter (Dm) of the masking plate 22, the thickness (t) of the holding frame 23, the diameter (Ds), and the protruding amount (w) on the inner diameter side. Through a subsequent firing step, irregularities are formed in the honeycomb flow path direction with a surface roughness of 20 to 500 μmRa.

  After the catalyst is supported on the fired ceramic honeycomb structure 12, the catalyst is accommodated in the metal container 11 via the support member 13, and then the metal container 11 and the exhaust manifold 14 are friction-welded, whereby the catalytic converter 50 shown in FIG. An exhaust system component connected to the manifold 54 is obtained. In the ceramic honeycomb structure 12 of the embodiment, the holding force of the ceramic honeycomb structure 12 by the holding member 13 does not decrease even when the metal container is expanded by the high-temperature exhaust gas. The body 12 does not move away and wear due to friction with the metal container 11 is reduced.

It is principal part sectional drawing which connected the catalytic converter of embodiment to the exhaust manifold by the friction welding. FIG. 1 shows a ceramic honeycomb structure in FIG. 1, (a) is a perspective view thereof, and (b) is a schematic diagram in which an outer peripheral surface is enlarged. It is an example of the unevenness | corrugation formed in three places (12a-a, 12a-b, 12a-c) in FIG. 2, and is an enlarged view which deform | transforms an unevenness | corrugation only to an up-down direction. (A) is an enlarged partial view after extrusion molding of the ceramic honeycomb structure, and (b) is a cross-sectional view of the main part of an extrusion mold. It is principal part sectional drawing which connected the conventional catalytic converter to the exhaust manifold with the volt | bolt. The ceramic honeycomb structure in FIG. 5 is shown, (a) is the perspective view, (b) is the schematic diagram which expanded the outer peripheral surface.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10,50 Catalytic converter 11,51 Metal container 12,52 Ceramic honeycomb structure 12a, 52a Outer peripheral surface 12b Concavity and convexity 12f Outer peripheral wall 13,53 Grasping member 14,54 Exhaust manifold 16 Pressure contact part 20 Extrusion mold 21 Die 21a Supply Passage 21b discharge passage 22 masking plate 23 holding frame 56 bolt

Claims (3)

A ceramic honeycomb structure housed in a metal container via a gripping member, wherein a convex portion substantially corresponding to a partition wall contacting the outer peripheral surface is substantially uniform in a flow path direction on the outer peripheral surface of the ceramic honeycomb structure. A ceramic honeycomb structure characterized by being formed. 2. The ceramic honeycomb structure according to claim 1, wherein the unevenness formed by the protrusions and the outer peripheral surface has a maximum surface roughness measured in the circumferential direction of 5 to 500 μm. The ceramic honeycomb structure according to claim 1 or 2, wherein the convex portion is formed by extrusion molding.

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